Monday, May 13, 2013

top ten of physics!

Top Ten Most Bizarre Facts I learned in Physics.... as they come into my head

10.



Notice anything truly bizarre about his video. Never mind the fact that Faith Hill is dwarfed by giant flowers, her riding on the outside of a rocket, or even when she swings on the cherry. No, its the fact that she says its a "centrifugal force" that is drawing her lover towards her!! First of all, Centrifugal forces are completely imaginary. Second of all, it is the inertia that repels the object from the center of rotation. So she is saying that 'this kiss' is imaginary and is repelling her lover because he was already moving to get away from her in the first place due to inertia. Talk about strong love!

9.




Quite beautiful huh? Who knew that the wonders that create this majestic lights are also key source in causing cancer! The light show is a result of cosmic rays entering the Earth's atmosphere, which usually protects us by a magnetic shield. However since at the poles the cosmic rays come not a perpendicular force but straight onward thus the cosmic rays do not feel a force. These cosmic rays can rip through DNA and cause cancer, making those at the poles more prone to cancer.

8. Once upon a time, Nikola Telsa got into a huge spiff with Thomas Edison about AC and DC current that went something like this....



Well maybe not exactly like that... but the point of the matter was that Tesla was right! AC always beats out DC (except in the case of batteries!! Why? Because of its efficiency!! AC current uses the change in the magnetic field to induce current. AC can produce high voltage with small heat losses and small use of current. This is because AC current can be controlled by coils of copper wire since it controls the amount of current and voltage going through the primary and secondary transformers. The more coils of wire the more voltage while less coils of wire have less voltage. Since this is related in terms of power, P=I X V and P(1)=P(2) transformers allow you to have either a small voltage and high current or a large voltage and small current.

7. Its amazing how much people get shocked! Its even more amazing that people are shocked due to the current going into the ground since it is actually the moving of electrons within your body that is causing the current. When the current transfers throughout your body and enters the ground, it creates a complete circuit. Therefore, if everyone knew when to jump when they are getting shock by an electric fence, the current would not be completed and thus they would not be shocked! so tragedies such as this would not happen, and people would no longer have to post funny, yet cruel videos on youtube



6. Did you know that Columbs law that attracts the force between teensy tiny atoms is almost exactly the same as the universal gravitational law that is used to measure the force between planets. Who knew that what happens on the teensiest scale also happens on a larger scale!! Pretty cool huh? It is because the both measure the forces between to objects whether it be charges or planetary bodies. The formula for Columbs law is F= K(q(1) x q (2)/ (d^2) while The universal gravitational formula is F= G(m(1) x m (2)/ D^2

5.

These solos are just too comprehension, right?? Nope, though they rock of epicness, physics explains the concepts behind their awesome sound. Within the guitar their are magnets, when the guitarist plucks a copper string his is creating a change in magnetic field  This change induces current which sends a signal for sound. Physics rocks hard!

4.

Wait, did that man walk across the Niagara falls with only a tight rope and a stick? Is that even possible? According to physics it is! The pole does two things, It increases the basis of support and increases the walkers rotational inertia. This means that the pole's center of balance is far away from its mass increasing its rotational inertia allowing the tightrope walker more time to adjust his footing.

3. We all know airbags save lives against harsh crashes.. Look at the difference of with and without airbags



But the reason they keep us safe is due to the conservation of momentum and impulse. Since momentum equal mass times velocity and the change of momentum means that the car goes from moving to not moving at all. However, no matter how you crash you will always have the same change in momentum. Impulse equals meaning impulse will remain the same regardless of how you are stopped. Since J= Force x Change in time, when we hit the airbags it increases our time which decreases our force in order to keep the Impulse the same. Without airbags it would be a large force and a small time period, however with airbags it is a large time period with a small force

2.

Whoa that girl spins fast, but how does she do it? Simple she decreases her rotational inertia by drawing all her mass closer to her because it is nearer to her center of rotational enabling her to spin crazy fast. this is because of conservation of angular momentum. Since the equation of angular momentum is Rotational inertia x velocity when she decreases her inertia her velocity must increase in order to compensate.

1. PHYSICS CAN ACTUALLY BE FUN..... wait what????????? CRAZY!

For, in physics you can apply what you learn to everyday life. When I went to watch baseball players bat, all I could think about is trajectory motion and vectors! When we made our motor our experimentation with current and how a motor converts electrical energy into mechanical energy was also super fun. I really enjoyed anything that had to do with current. Even learning about free fall had its perks as we dropped balls from third Anderson without even getting into trouble!

Wednesday, May 1, 2013

final unit post!!!


We began the semester off learning about magnetism. For, the source of all magnetism is electrically charged particles. When these particles align when the spin or have aligned domains, it causes magnetism. When a magnet is magnetized it has north and South Pole and a magnetic field. Magnetic field lines run from north to south outwardly and south to north inwardly. They explain why only opposite poles attract since the fields lines are running in the same direction. A common example of this concept is magnetizing a paperclip. To begin with the paperclip is neutral however when it comes near the magnets magnetic field, it causes the paper clips domains to align causing polarization. Since the internal field lines are in the same direction, the paper clip sticks. Magnetic fields also work with the earth. They protect us from cosmic rays. However, since the cosmic rays can only feel a force if they perpendicular to the magnetic field, the cosmic rays that hit the poles are parallel and thus the particles do not feel a force and can enter the earth’s atmosphere.

Next we learned about motors. Motors convert electrical energy into mechanical energy. They work when a current carrying wire is exposed to a magnetic field. Since the magnetic field is perpendicular to the current, it feels a force and thus resulting in a torque for the wire to spin easier and for longer. Such use of this method has been used from lawn mowers to fans.

Next we learned about electromagnetic induction. This means that the change of magnetic field causes current. This concept is applied to many of useful everyday technology such as traffic lights or credit card machines. For instance, within the credit card is a series of magnets and within the credit card machine there is a loop of wire. The magnets cause a change in the magnetic field causing current, which sends a signal to the credit card machine.

Finally we learned about transformers. Transformers affect how much current and voltage goes into appliances or even our households. There are two types of transformers step up and step down. We use step up with our power lines. Since current causes heat and the power lines could become overheated, there is less current going through them than what it takes to run a household. However the current goes through a transformer which has a primary coil which it enters and a secondary coil which it travels to the house In order for the transformer to work it must have AC current for there to be a change in the magnetic field. For the house there are less coils of wire in the primary coil than the secondary. The secondary produces more current for the household and creates efficient energy.

I really enjoyed this unit and I have come to understand it better than I have most. My greatest problem with this unit was figuring out AC currents affect with magnetic fields. However, I have grasped it more strongly due have to work on the podcast that deals with that particular topic. To improve in the future, I hope to try to apply this unit to more everyday activities instead of just trying to memorize the principles. Otherwise, it has been one of my favorite units and it has been a electrifying final unit.

Thursday, April 18, 2013

How to build a motor

Today, Mrs. Lawrence taught us how to build a motor out of a battery, two paper clips, copper wire, a rubber band, and a magnet with the goal for the copper wire to have torque to spin. To create such a contraption, you must attach the two papers clips to each side of the battery to hold the looped and coiled copper wire on top of them so that it is suspended over a magnet which is placed on top of the battery. The battery creates the current which the copper wire will carry. The two paperclips will complete the circuit. The magnet creates an magnetic field around the copper wire. This is important because the magnetic field causes a force on the moving electrons within the current. This is how it is similar to cosmic rays. Since both the current in the copper wire and the cosmic rays within the atmosphere are perpendicular to the magnetic field, both feel a force and are rejected by the magnetic field. If they were parallel they would not feel any force at all, causing the motor not to move and the cosmic rays to penetrate the magnetic field. It is also important to note that you must scrape the plastic off the copper wire to complete the circuit. However, it must only be on one side because it must only feel on force to propel it all the way around. If it was scraped all the way around it would feel to opposing forces that would cause it to go back and forth back and forth.

Just as moving charges are the sources of all magnetism, they are also the source of the motor. It is caused by the magnet creating a torque within the magnetic field since its force is perpendicular to the copper wire. The paper clips complete the circuit and cause the copper wire to hover over the magnet while the rubber band holds the two paperclips in place. It is easy to see how this is applicable to everyday life as the same sort of design is used in the motors of cars, blenders, and fans to propel wheels and blades.

http://www.youtube.com/watch?v=tO0qP7NYqOU

Tuesday, April 16, 2013

Magnetic Nail: a fun, at-home science experiment

This video shows how to make a magnet and provides clear explanation about how the electrons align to the magnetic field in order to create the same domain, by using a simple experiment for an example

Wednesday, April 10, 2013

Unit 6


We began this unit of Electricity by learning how a circuit works. We learned that a circuit to be complete it must travel from a high voltage to a low voltage. Also, the circuit needs to be closed or else the circuit will not be complete and will not carry the current and there will be no electrical flow. This is why when a light bulb filament breaks; there is no light afterwards. We learned a great example of how current and circuits work.  We learned that the electrical shock you receive such as when you touch an electrical fence is actually caused by the flow of current going through your body and into the ground. If you stood on an insulator or jumped when you touched the circuit, the current would not be able to go into the ground  and thus the circuit would not be complete and you would not receive an electric shock.
After this, we learned about charge and the types of charge, such a positive, negative, and neutral charges. After understanding that like charges repel and opposite charges attract we then learned about the transferring of charges. We learned there were three main methods of transferring charges were direct contact, friction, and induction. We learned about how induction creates lightning storms, as the molecules within the cloud become negatively charged, and cause the positive protons in the ground to rise. This creates a pathway for lightning to form.
Next we learned about polarization or the separation of charges within an object. For instance, if a negatively charged balloon comes near a neutral wall, the attraction between the negative and positive ions will cause the wall to become polarized, yet still neutral. However, this introduces a new law called Columb’s law which states that the force between charges is inversely proportional to distance squared or otherwise know as Columbs Law: K(q1)(q2)/d2. This is why electronics are placed in metal containers, because according the columbs law the magnetic charges will be equal and opposite to each other created functional balance within the hard drive.
Next we learned about voltage which is the difference in potential energy it is also defined by the formula V=PE/Q. We learned that voltage creates current and that voltage is not necessarily dangerous but current is. Current is the transfer of energy or is dictated by ohms law as I=V/R. R is resistance or an object’s ability to resist current. Resistance is affected by temperature as well as length and thickness of an object. For instance, a light bulb will not blow if its been on a while because its resistance increased with the heat. It will blow when its been just turned on as the filament is cooler and cannot have the resistance to withstand a strong current. We then learned there are two types of current direct current and alternating current. We learned that most households have alternating current. Finally we concluded learning about series and parallel wiring. IN series all the outlets share the same current and circuit while in parallel they are all independent of each other. Most houses are wired in parallel because that way if you shut one appliance off it does not ruin the rest of the circuit and everything can work independently of everything else. However, it is important to have a fuse wired in series to control the parallel since with each appliance added you create a stronger current and a weaker resistance so to avoid potential fires the fuse will cut off the circuit ending the potential threat.

All in all this chapter has been one of the longer ones considering the many interruptions and other factos. My biggest issue with the chapter was retaining the information and preparing for the quizzes. I believe I overcame such obstacles by just becoming more familiar with the topics at hand and trying to review ass much as possible I did notice that the test did seem much easier. For next unit, I hope to learn the information before the quizzes instead of after the quizzes and hope to be more dependent on my notes and the given lectures.

Monday, April 8, 2013

Fluorescent light!

 This a picture of a single fluorescent light bulb. Notice how bright it is shining considering it is only thirteen watts. Compared to incandescent bulbs, which converts much of its energy to heat, the fluorescent lamps barely use any energy converted into heat. Therefore, a 100-W incandescent light bulb shares the same brightness as a 13-W fluorescent light bulb. The fluorescent lightbulb uses gases such as argon and mercury to cause a reaction inside the lightbulb to cause UV rays which is used a form of light.

Wednesday, February 27, 2013

Mouse Trap Car

How Newton's first, second, and third laws apply to the performance of the car

              First Law: An object in motion will stay in motion, and object at rest will stay at rest unless acted upon by an outside force. In other words, the mouse trap car will not move unless an outside force will cause it to move (the string attached to the axis). It will keep moving unless an outside force acts upon it (Friction, or in our case, a wall)

              Second Law: A=F/M. To obtain a greater acceleration, you need to trim down the mass of the car as well as apply more force to the car, which usually means wind up the rope nice and tight.

            Third Law: Every action has an equal and opposite reaction. When the mouse trap wheels push backward against the ground the ground propels the car forward.


What are the two types of friction present? What Problems related to friction did you encounter and how did you solve them? How did you use friction to your advantage?
                 
                     The two types of friction is the friction created between the wheels and the floor to get it moving in the first place, which is known as static friction, and then there is kinetic friction or the resistance against a moving object. Friction took part in two key places. Firstly, the friction between the wheels and the ground provided stabilization, yet at the cost of speed. The other force of friction took place between the wheels and the axel. The more frictionless the wheels of the car were, the easier it was to spin and travel faster.
 At first, we had to overcome static friction to make our car move in the first place, we did so by adding more string and widening the axel to create more force to overcome the frictional barrier. However, we created traction between the floor and the tire by adding tape to help stabilize the car.

What factors did you take into account to decide the number of wheels? What kind of wheels did you use in each axle?

Stabilization was a key factor in choosing to have four wheels. Also, we felt that the wheels would complement the body of the car better than one wheel. Furthermore, We wanted our wheels to be generally larger in the back so we would have a greater tangential velocity or cover more ground per rotation. Therefore we chose CDS for the back. Another reason for using CDs is that they lack mass which causes a greater acceleration, Newtons Second Law. Finally, since the axel of the CD were much smaller than the outside, if the CDs had the same RPM the outside wheels would have to travel a lot faster to keep up with the axel.

Discuss the conservation of energy in how it relates to your car.

Since energy cannot be created nor destroyed, the more potential energy you have built up the farther you car will go because it has more energy. For example, you want a taut string compared to a loose string because their is more potential energy built up within the string and therefore has more force to convert into kinetic energy. Since Kinetic energy equals the change in work, the more kinetic energy you have the more work has been done.

What role did rotational inertia, rotational velocity, and tangential velocity play in your mousetrap car?
 Rotational Inertia, particularly affects your starting acceleration. Therefore to decrease your rotational inertia, you want wheels with a smaller mass and more traction.

Rotational velocity is the amount of rotations per second. Rotational velocity actually was a problem with our mousetrap since the front wheels were moving having to rotate faster to keep up with our back wheels which had a greater tangential speed. Because of this, it caused our mouse trap to taper, twist, and turn so that it did not make it to the finish line.

Tangential velocity is the distance traveled over time. It is important to have a high tangential velocity so you can go faster. To achieve a higher tangential velocity, you must have larger wheels that can travel a greater distance per rotation.

The reason you cannot calculate work is because the force is not parallel to the distance it moves. In other words, you cannot calculate the force because you cannot calculate the work. Finally you cannot calculate the kinetic/potential energy because the velocity of the mouse trap car is not constant

I have encountered many successes as well as failures when building this mouse trap car. First and foremost, I wish we kept our designs simple from the beginning instead of trying more complex and complicated designs. It would have saved us time and effort. Next, I wish we used our resources more readily at will such as the five dollars instead of trying to fix what we had. Finally, I wish we made our changes carefully and easily. We often made rash and critical changes to our car, and that put us behind schedule and ended up costing us more work. However, what I did learn victoriously was perserverance and patience, and in the end hard work did pay off.

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